Port-to-port network routing using a storage device

ABSTRACT

A multi-port data storage device to at least provide port-to-port communication between nodes. The multi-port storage device includes a first port, a second port and a bridge. The first port can be operatively coupled to a first node of a plurality of nodes. The second port can be operatively coupled to a second node of the plurality of nodes. The bridge can receive one or more data packets via the first or second ports to be transmitted to one of the plurality of nodes and to transmit one or more received data packets to another multi-port data storage device, to the first node, or to the second node.

RELATED APPLICATIONS

This application is as continuation of U.S. application Ser. No.16/724,602 filed on Dec. 23, 2019, which is incorporated herein byreference in its entirety.

The present disclosure relates to network routing. In particular, thepresent disclosure relates to port-to-port network routing and dataflowusing a storage device.

SUMMARY

Various embodiments of the present disclosure relate to port-to-portnetworking using data storage devices. A data storage device may providea link between nodes. The data storage device may receive a data packetand transmit the received data packet to one of the nodes of anotherdata storage device providing a link to one of the nodes.

In at least one embodiment, an exemplary multi-port data storage devicemay include a first port, a second port and a bridge. The first port maybe operatively coupled to a first node of a plurality of nodes. Thesecond port may be operatively coupled to a second node of the pluralityof nodes. The bridge may be configured to receive one or more datapackets via the first or second ports to be transmitted to one of theplurality of nodes and to transmit one or more received data packets toanother multi-port data storage device, to the first node, or to thesecond node.

In at least one embodiment, an exemplary port-to-port network routingsystem may include a plurality of nodes and a plurality of multi-portdata storage devices. The plurality of nodes may be configured to atleast receive, transmit, and store data. Each of the plurality of nodesmay include a memory and a data bus operatively coupled to the memory.The plurality of multi-port data storage devices may be configured to atleast provide port-to-port communication between nodes. Each of theplurality of multi-port storage devices may include a first port, asecond port, and a bridge. The first port may be operatively coupled tothe data bus of a first node of a plurality of nodes. The second portmay be operatively coupled to the data bus of a second node of theplurality of nodes. The bridge may be configured to receive one or moredata packets via the first or second ports to be transmitted to one ofthe plurality of nodes and to transmit one or more received data packetsto another multi-port data storage device, to the first node, or to thesecond node.

In at least one embodiment, an exemplary method can include receiving adata packet via a first port of a multi-port data storage device using abridge of the multi-port data storage device; and transmitting the datapacket via a second port of the multi-port data storage device using thebuffer to one of another multi-port data storage device, to a first nodeoperatively coupled to the multi-port data storage device, or to asecond node operatively coupled to the multi-port data storage device.

The above summary is not intended to describe each embodiment or everyimplementation of the present disclosure. A more complete understandingwill become apparent and appreciated by referring to the followingdetailed description and claims taken in conjunction with theaccompanying drawings. In other words, these and various other featuresand advantages will be apparent from a reading of the following detaileddescription.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosure may be more completely understood in consideration of thefollowing detailed description of various embodiments of the disclosurein connection with the accompanying drawings.

FIG. 1 is a schematic diagram of an example network using multi-portdata storage devices as links between nodes.

FIG. 2 is a schematic block diagram of an example multi-port datastorage device for operations in accordance with embodiments of thepresent disclosure.

FIG. 3 is a schematic block diagram of an example node for operations inaccordance with embodiments of the present disclosure.

FIG. 4 is a schematic block diagram of an example of network routingoperations in accordance with embodiments of the present disclosure.

FIG. 5 is a schematic block diagram of an example data packet inaccordance with embodiments of the present disclosure.

FIG. 6 is a flowchart of an example method in accordance withembodiments of the present disclosure.

FIG. 7 is a flowchart of another example method in accordance withembodiments of the present disclosure.

DETAILED DESCRIPTION

The present disclosure relates to systems, methods, and processes forport-to-port network routing using data storage devices, such asmulti-port data storage devices. Although reference is made herein tonodes, devices, and storage devices, data may be stored in any suitabledata storage system with available storage space that stores data ondifferent devices or nodes. Non-limiting examples of data storagedevices include non-volatile and volatile memory, hard disk drives,solid state drives, and multilayer drives (for example, utilizing bothhard disk and solid state). Various other applications will becomeapparent to one of skill in the art having the benefit of the presentdisclosure.

Moving data through a network can be expensive. Data storage devicessuch as solid-state drives (SSD) may be in an operating mode where thehost interconnections are underutilized due to low queue depth, mixedreads and writes, or small transfer sizes. A virtual network functionmay be instantiated in the data storage device such that network trafficcould pass through from one port of the data storage device to another.A mesh or other network topology could be created using the data storagedevices to link compute complexes or nodes without the cost or powerconsumption of a network adapter and switch.

Current data bus architectures such as peripheral component interconnectexpress (PCIe) support virtual functions. Instantiating a virtualnetwork function in a data storage device may allow one hardwareconnection to present multiple virtual devices to the operating system.By configuring each port of a multi-port data storage device (MDSD) topresent one or more network functions, the MDSD can read/write datalocally stored within the device and pass network traffic through to theother ports to the limits of data bus rate. A collection of computecomplexes or nodes in a multidimensional mesh topology can provide costreductions and increased throughput. In one example, each node has 6PCIe by 4 lane busses then a 3-dimensional mesh can be configured withMDSDs providing connections to 6 adjacent servers. Each MDSD drive maybe a dual-port dual-lane drive that provide 2 GB/s simplex and 4 GB/sduplex for each link. Six links enable 24 GB/s per node using PCIe Gen3. PCIe Gen4×4 may provide 96 GB/s per node. This amount of traffic maynot be bridged by a store and forward operation by the node centralprocessing unit (CPU).

The MDSD may write data packets directly (e.g., direct memory access)via each port to the next MDSD in the path of communication between thesource and destination nodes. Direct memory access is a feature ofcomputer systems that allows certain hardware subsystems to accessmemory independent of the central processing unit (CPU). In other words,the MDSD may write data packets to other devices or MDSDs without usingCPUs or memory of operably coupled nodes. The MDSD may include a bridgeconfigured to carry out the operations described herein. Although thebridge may be described as carrying out the operations described herein,the MDSD may include a processor or controller to carry out theoperation of the bridge. The bridge may include a buffer to providestore and forward functionality.

The topology of the network may be discovered at initialization so thatnode and link connections are known to operably coupled nodes of thenetwork. Then the source node's network driver may select one or morepaths to the destination for each data packet or datagram. The one ormore paths or route guidance may be appended to the data packet andwritten to a bridge. This bridge may be in host memory. A notificationmay be sent to the MDSD to read/transmit or it could be written directlyinto a pre allocated bridge in the drive. Route guidance may be offeredin vectors (e.g., east-2, west-1, up-1). Accordingly, all of the baseaddress registers for all the nodes (e.g., servers) may not have to beshared to all nodes. Instead, the egress port of the MDSD may know thememory location for vectors of its node. When the egress port pushes thedata packet to the MDSD at such vector, it may decrement that vector.Thus. a method for changing the route due to dataflow backpressure orserver failure may be enabled.

Data packets can be cut through the drive to avoid store and forwardlatency. Cut through logic may start issuing the data on the egress portprior to reception of the full data packet. To enable recoverymechanisms a footer may be appended to the data which includes agood/bad transmission indication along with other possible data liketimestamps and sequence numbers.

Data packet route selection at each link or node may be based on egressID (EID) congestion or bandwidth utilization. Routing methods mayinclude and suitable process or method such as, e.g., a round robinselection of possible paths, an egress option or options stored in arace header of the data packet at data packet generation, least used EIDselection, etc.

FIG. 1 shows a schematic diagram of a network 10 for using multi-portdata storage devices (MDSD) 12 as links between nodes 14. In otherwords, network 10 may be a port-to-port network routing system.

Each of the nodes 14 of the network 10 is linked to at least one othernode 14 using a MDSD 12. Each MDSD 12 may include at least two ports. Afirst port may be operably coupled to a first node and a second port maybe coupled to a second node of the nodes 14. In some embodiments, one ormore of the MDSDs 12 may include more than two ports. Each port of theMDSDs 12 may be operatively coupled to a different node 14. Accordingly,the nodes 14 may be linked by the MDSDs 12 into any suitable networktopology such as, e.g., ring, mesh, star, fully connected, Dragonflly,Slimfly, Toroid, etc. In at least one embodiment, the network 10 isarranged in a Slimfly topology.

FIG. 2 is a schematic block diagram of an example multi-port datastorage device (MDSD) 12 for a network in accordance with embodiments ofthe present disclosure similar to as shown in FIG. 1 . The MDSD 12 mayinclude a bridge 16 and ports 18 and 20. The MDSD 12 may include anysuitable device such as, e.g., a solid-state storage device (SSD), anon-volatile memory express (NVMe) device, etc. The MDSD 12 may includea data encryption engine 17 and decryption engine 19. The MDSD 12 mayfurther include a processor 13 and a memory 14. The processor 13 mayexecute operations of the MDSD 12 as described in various embodimentsherein.

Ports 18 and 20 may each be operatively coupled to a different node of anetwork such as, e.g., network 10 of FIG. 1 . Such an arrangement allowsMDSD 12 to transmit and receive data packets via ports 18 and 20. Ports18 and 20 may include any suitable connector for operatively coupling toa data bus such as, e.g., SATA, PCIe, M.2, U.2, mSATA, SATA Express,etc. In at least one embodiment, each of ports 18 and 20 include a PCIeconnector. The two ports 18 and 20 may include an input output (io) bus.Although shown with only two ports 18 and 20, MDSDs such as the MDSD 12may include more than two ports such as, e.g., 3 ports, 4 ports, etc.Each port of the MDSD 12 may be operatively coupled to a different node.

The bridge 16 may receive data packets via each of ports 18 and 20. Thebridge 16 may be configured by a virtual network function. The bridge 16may be configured to transmit received data packets to any operativelycoupled node or to any MDSD operatively coupled to such nodes. Forexample, the bridge 16 may receive a data packet from a first node viaport 18. The bridge 16 may transmit the received data packet to a secondnode or a MDSD operatively coupled to the second node via port 20. Thebridge 16 may be configured to receive data packets via direct memoryaccess. Additionally, the bridge 16 may be configured to transmit datapackets via direct memory access. Such a configuration allows cutthrough logic that may eliminate store and forward latency. Furthermore,the bridge 16 may be configured to receive and transmit data packetswithout using processors of operably coupled nodes. In other words, thebridge 16 may not need an external processor to execute networkfunctions.

In one embodiment, the bridge 16 receives one or more data packets viaport 18 or port 20 to be transmitted to one of a plurality of nodes andto transmit one or more received data packets to another MDSD, to a nodevia port 18, or to a node via port 20. The bridge 16 may be configuredto transmit one or more received data packets to another MDSD, to a nodevia port 18, or to a node via port 20 based on a destination address ofeach of the received data packets. The bridge 16 may be configured todecrement a passthru limit of the received one or more data packets. Thebridge 16 may be configured to prohibit transmission of packets receivedwith a passthru limit of 0.

The bridge 16 may include a buffer. The buffer may be configured toreceive a data data packet for transmission. The buffer may providestore and forward capabilities. The buffer may be any suitable buffersuch as, for example, a ring buffer, a first in first out buffer, aqueue, etc. In at least one embodiment, the buffer is a ring buffer.

In at least one embodiment, the data encryption engine 17 may transformdata of a payload portion of the data packet such that transmission viaport 20 is encrypted. The data of the payload may be encrypted using anysuitable encryption method such as, for example, the Advanced EncryptionStandard (AES) using the source node's private key and destination nodespublic key. In at least one embodiment, the data decryption engine 19may transform the data of the payload portion of the data packet sotransmission via port 20 is the original data payload issued by thesending node. One example of decryption method would be embodiment ofthe Advanced Encryption Standard (AES) using the source node's publickey and destination nodes private key.

FIG. 3 is a block diagram of an example node 14 for a network inaccordance with embodiments of the present disclosure. The node 14 mayinclude a central processing unit (CPU) 30, a memory manager 32, a databus 34, a network interface controller (NIC) 36, and data storagedevices 38. The node 14 may include any suitable computing apparatussuch as, e.g., a personal computer, a compute complex, a server, etc.

The CPU 30 may include one or more processors, controllers, memories,caches, PCIe Bridges, other data busses, etc. The CPU 30 may beoperatively coupled to the data bus 34. The CPU 30 may be configured togenerate data packets, use the MDSDs 12 to discover other nodes, processinterrupts, and manage MDSD data bridging exceptions and faults. Thememory manager 32 may include any hardware or software suitable todynamically allocate portions of memory for program execution andenumeration of MDSDs within an address space of the CPUs 30.

The data bus 34 may include any suitable bus apparatus and protocol suchas, e.g., a PCIe bus, a HyperTransport bus, an InfiniBand bus, ComputeExpress Link, or other suitable bus for operatively coupling datastorage devices. In at least one example, the data bus 34 is a PCIe bus.The data bus 34 may be operably coupled to data storage devices or otherperipheral computer components.

The NIC 36 may be operably coupled to the data bus 34. Additionally, theNIC 36 may be operably coupled to an external network. The NIC 36 mayinclude any suitable apparatus to transmit and receive data packets suchas, e.g., a memory, processor, etc. The NIC 36 may allow the node 14 tocommunicate with networks external to a port-to-port network usingstorage devices. The NIC 36 may be operably coupled to any suitablecommunication medium such as, e.g., an ethernet cable.

The data storage devices 38 may be operably coupled to the data bus 34.The data storage devices 38 may include any suitable storage device orapparatus such as, e.g., SDDs, NVMe devices, random access memory (RAM),hard disc drives (HDDs), Serially Attached Small Computer SystemInterface (SAS) host bus adapters, etc. The data storage devices 38 maystore data, programs, databases, data objects, data replicas, filesystems, point in time snapshots, etc.

The node 14 may be operably coupled to MDSDs 12. The node 14 may beoperably coupled to the MDSDs 12 via the data bus 34. As such, the node14 can transmit data packets to other nodes via the MDSDs 12. Thisallows the node 14 to utilize the bandwidth and speed of the data bus 34and the MDSDs 12. The node 14 may be configured to transmit data packetsto the MDSDs 12 using direct memory access.

FIG. 4 is a schematic diagram of an example of a network 48 and networkrouting operations in accordance with embodiments of the presentdisclosure. The network 48 may include nodes 50A-50C and MDSDs 56, 58,60, 62, 66, 68, 70, 72, 74, 78, 80, 82, 84, 86, 88, and 90. Nodes50A-50C may each include the configurations and apparatus of nodes 14 ofFIGS. 1 and 3 . MDSDs 56, 58, 60, 62, 66, 68, 70, 72, 74, 78, 80, 82,84, 86, 88, and 90 may each include the configurations and apparatus ofMDSD 12 of FIGS. 1-3 .

Node 50A may include network driver 52A and a memory 54A. Node 50A maybe operatively coupled to MDSD 56 via port A1, MDSD 58 via port A2, MDSD60 via port A3, MDSD 62 via port A4, MDSD 66 via port A5, and MDSD 68via port A6. Each of MDSDs 56, 58, 60, 66, and 68 may be operativelycoupled to another node (not shown). MDSD 62 is operatively coupled tonode 50A via port A4 and node 50B via port B1.

Node 50B may include network driver 52B and a memory 54B. Node 50B maybe operatively coupled to MDSD 62 via port B1, MDSD 70 via port B2, MDSD72 via port B3, MDSD 74 via port B4, MDSD 78 via port B5, and MDSD 80via port B6. Each of MDSDs 70, 72, 78, and 80 may be operatively coupledto another node (not shown). MDSD 74 is operatively coupled to node 50Bvia port B4 and node 50C via port C1.

Node 50C may include network driver 52C and a memory 54C. Node 50C maybe operatively coupled to MDSD 74 via port C1, MDSD 82 via port C2, MDSD84 via port C3, MDSD 86 via port C4, MDSD 88 via port C5, and MDSD 90via port C6. Each of MDSDs 82, 84, 86, 88, and 90 may be operativelycoupled to another node (not shown).

Network drivers 52A-52C may be configured to generate data packets forport-to-port networks such as network 48. Network drivers 52A-52C mayinclude a network map including the nodes of the network and theirassociated links (e.g., MDSDs 56, 58, 60, 62, 66, 68, 70, 72, 74, 78,80, 82, 84, 86, 88, 90, etc.) to one another.

At step 92, the network driver 52A may write one or more data packetsinto bridge 64 of MDSD 62. The network driver 52A may write the one ormore data packets into bridge 64 using direct memory access. The networkdriver 52A may write a send request to MDSD 62 with the location inmemory of the data packet for the MDSD 62 to fetch. The bridge 64 mayencrypt the fetched data packet. The network driver 52A may select theMDSD 62 based on a destination address of the one or more data packets.

At step 94, bridge 64 transmits the one or more data packets by writinginto bridge 76 of the MDSD 74. The bridge 64 may write the one or moredata packets into bridge 76 using direct memory access. The bridge 64may select the bridge 76 based on the destination address of each of theone or more data packets. At step 96, the bridge 64 may notify thenetwork driver 52A that the transmission of the one or more data packetsvia the MDSD 62 is complete.

At step 98, the bridge 76 writes one or more data packets into thememory 54C. The bridge 76 may write the one or more data packets intothe memory 54C using direct memory access. The bridge 76 may select thememory 54C based on the destination address of each of the one or moredata packets. The bridge 76 may decrypt the data packet. At step 100,the bridge 76 may notify bridge 64 that the transmission of the one ormore data packets via MDSD 74 is complete. At step 102, the networkdriver 52C may notify the bridge 76 of complete reception of the one ormore data packets.

FIG. 5 is a schematic block diagram of an example data packet 110 inaccordance with embodiments of the present disclosure. The data packet110 may include a race header 112, protocol headers 124, and a payload126. The data packet 110 may optionally include a trace footer 128.

The race header 112 may include information for port-to-port networkrouting. The race header 112 may include a destination address 114, asource address 116, a route class 118, a passthru counter 120, and atrace footer word count 122.

The destination address 114 may include any suitable identifier of theintended destination of the data packet 110. In other words, thedestination address 114 identifies the node or other device intended toultimately receive the data packet 110. Suitable identifiers may includethe media access control (MAC) address, a physical address, an internetprotocol address, host unique identifier, application unique identifier,etc. In at least one example, the destination address 114 includes theMAC address of the intended destination of the data packet 110.

The source address 116 may include any suitable identifier of the sourceof the data packet 110. In other words, the source address 116identifies the node or other device that generated the data packet 110.Suitable identifiers may include the media access control (MAC) address,a physical address, an internet protocol address, host uniqueidentifier, application unique identifier, etc. In at least one example,the source address 116 includes the MAC address of the source of thedata packet 110.

The route class 118 may include an indicator of a priority level of thedata packet 110. Data packets with a higher priority level or routeclass may be pushed or transmitted through routes with fewer hopsregardless of congestion along such routes. In contrast, data packetswith a lower priority level or route class may be pushed or transmittedthrough routes with higher hop counts to avoid congested or heavily usedroutes. Data packets of higher priority may be transmitted ahead ofprior received packets of lower priority.

The passthru counter 120 may include a maximum number of hops or links(e.g., MDSDs 12 of FIGS. 1-3 ) that the data packet 110 is permitted topass through. The passthru counter 120 may be decremented each time thedata packet 110 is received by a MDSD of a port-to-port network. TheMDSD may prohibit transmission the data packet 110 if the passthrucounter 120 is at zero prior to being decremented and the destinationaddress 114 is not for an operatively coupled node. The MDSD may send ortransmit a notification to the source address 116 when the data packet110 is prohibited.

The trace foot word count 122 may record the number of hops or links(e.g., MDSDs 12 of FIGS. 1-3 ) that the data packet 110 has passedthrough. The trace foot word count 122 may further include an indicationof which MDSDs the data packet 110 has passed through.

The protocol headers 124 may include information for proper externalnetwork routing. The protocol headers 124 may include any suitablenetwork headers such as, e.g., Internet Protocol (IP) headers, UserDatagram Protocol (UDP) headers, Transmission Control Protocol (TCP)headers, Transactional Transmission Control Protocol (T/TCP) headers,etc.

The payload 126 may be the data to be transmitted to a node or otherlocation. The payload 126 may not altered once the data packet 110 isgenerated. The data packet 110 may include a checksum to verify theintegrity of the payload 126 upon delivery of the data packet 110 to theintended destination.

The trace footer 128 may include slot identification (ID) 130, queuedepth 132, and a timestamp 134. The slot ID 130 may include anindication of the location of the intended destination of the datapacket 110 within the port-to-port network (e.g., network 10 of FIG. 1). The slot ID 130 may be determined based on the destination address114. The slot ID 130 may further be determined based on a comparison ofthe destination address 114 and a list of MAC addresses mapped to slotIDs of the port-to-port network. The slot ID 130 may also include anMDSD identifier, propagation time through the MDSD, bridge utilization,historical throughput metrics, route congestion, etc.

The queue depth 132 may include an indication of the maximum queue depthper class or route class. The time stamp 134 may indicate when the datapacket 110 was generated or created. The time stamp 134 may be used todetermine a transmission time of the data packet 110. The time stamp 134may be used to determine an age of the data packet 110 duringtransmission.

FIG. 6 is a flowchart of an example method 140 in accordance withembodiments of the present disclosure. The method 140 can includereceiving a data packet via a first port of a multi-port data storagedevice using a bridge of the multi-port data storage device 142. Thedata packet can be received from a node or another multi-port datastorage device. The data packet can be received via direct memoryaccess.

The method 140 can include transmitting the data packet via a secondport of the multi-port data storage device using the bridge to one ofanother multi-port data storage device, to a first node operativelycoupled to the multi-port data storage device, or to a second nodeoperatively coupled to the multi-port data storage device 144. The datapacket can be transmitted using direct memory access. The data packetcan be transmitted without using processors of the first and secondnodes. The data packet can be transmitted to one of another multi-portdata storage device, to the first node, or to the second node based on adestination address of the packet. Transmitting the data packet mayfurther comprise selecting the one of another multi-port data storagedevice based on egress ID (EID) congestion or bandwidth utilization andtransmitting the one or more packets to the selected one of anothermulti-port data storage device.

FIG. 7 is a flowchart of an example method 150 for route selection inaccordance with embodiments of the present disclosure. The method 150for route selection may be based on egress ID (EID) congestion orbandwidth utilization. The method can include selecting an EID with thelowest hop count 152. An EID may include the local port address of MDSDsoperably coupled to a given node.

The method 150 can include determining whether one or more EIDs have nobacklog. If one or more EIDs have no backlog the method 150 can proceedto step 156. If there are no EIDs with no backlog the method 150 canproceed to step 164.

The method 150 can include determining whether all EIDs of the selectionset have no recent activity 158. The method 150 can proceed to step 160if all EIDs of the selection set have no recent activity. The method 150can proceed to step 168 if any HD of the selection set has had recentactivity. Recent activity may be within a range of about 1 microsecondto about 100 seconds.

The method 150 can include routing the data packet to a random EID ofthe selection set 160. The method 150 can include selecting a set ofEIDs with a next higher hop count 162. When all EIDs of the currentselection set exceed the backlog threshold and there are more EIDs witha higher hop count than the current selection set, an EIDs with a higherhop count may be selected to generate a new selection set.

The method 150 can include determining if all EIDs of the currentselection set exceed a backlog threshold 164. The backlog threshold maybe a maximum queue depth for data to be transmitted. The backlogthreshold may be about 4 kilobytes (4096 bytes) of data to about 1megabyte (1,048,576 bytes) of data.

The method 150 can include omitting EIDs from the selection set thatexceed the backlog threshold 166. Omitting EIDs may include removingsuch EIDs from the selection set. The method 150 can include routing thedata packet to the least used EID of the selection set 168.

The method 150 can include determining if there are more EIDs with ahigher hop count 170. If there are more EIDs with a higher hop count themethod 150 can proceed to step 162. If there are not more EIDs with ahigher hop count the method can proceed to step 172. The method 150 caninclude selecting EIDs with the lowest hop count 172.

Thus, various embodiments of PORT-TO-PORT NETWORK ROUTING USING ASTORAGE DEVICE are disclosed. Although reference is made herein to theaccompanying set of drawings that form part of this disclosure, one ofat least ordinary skill in the art will appreciate that variousadaptations and modifications of the embodiments described herein arewithin, or do not depart from, the scope and spirit of this disclosure.For example, aspects of the embodiments described herein may be combinedin a variety of ways with each other. Therefore, it is to be understoodthat, within the scope of the appended claims, the claimed invention maybe practiced other than as explicitly described herein.

All scientific and technical terms used herein have meanings commonlyused in the art unless otherwise specified. The definitions providedherein are to facilitate understanding of certain terms used frequentlyherein and are not meant to limit the scope of the present disclosure.

Unless otherwise indicated, all numbers expressing feature sizes,amounts, and physical properties used in the specification and claimsare to be understood as being modified in all instances by the term“about.” Accordingly, unless indicated to the contrary, the numericalparameters set forth in the foregoing specification and attached claimsare approximations that can vary depending upon the desired propertiessought to be obtained by those skilled in the art utilizing theteachings disclosed herein.

Reference to “one embodiment,” “an embodiment,” “certain embodiments,”or “some embodiments,” etc., means that a particular feature,configuration, composition, or characteristic described in connectionwith the embodiment is included in at least one embodiment of thedisclosure. Thus, the appearances of such phrases in various placesthroughout are not necessarily referring to the same embodiment of thedisclosure. Furthermore, the particular features, configurations,compositions, or characteristics may be combined in any suitable mannerin one or more embodiments.

As used in this specification and the appended claims, the singularforms “a,” “an,” and “the” encompass embodiments having pluralreferents, unless the content clearly dictates otherwise. As used inthis specification and the appended claims, the term “or” is generallyemployed in its non-exclusive sense meaning “and/or” unless the contentclearly dictates otherwise.

As used herein, “have,” “having,” “include,” “including,” “comprise,”“comprising” or the like are used in their open ended sense, andgenerally mean “including, but not limited to”. It will be understoodthat “consisting essentially of,” “consisting of,” and the like aresubsumed in “comprising,” and the like.

The phrases “at least one of,” “comprises at least one of,” and “one ormore of” followed by a list refers to any one of the items in the listand any combination of two or more items in the list.

What is claimed is:
 1. A multi-port data storage device comprising: afirst port; a second port; and a bridge to receive one or more datapackets via the first or second ports to be transmitted to a destinationexternal to the multi-port data storage device and to transmit one ormore received data packets via the first or second ports based on adestination address of each of the one or more data packets.
 2. Themulti-port data storage device of claim 1, wherein the bridge isconfigured to receive one or more data packets via direct memory access.3. The multi-port data storage device of claim 1, wherein the bridge isconfigured to transmit the one or more received data packets usingdirect memory access.
 4. The multi-port data storage device of claim 1,wherein the first port is operatively coupled to a data bus the secondport is operatively coupled to another data bus.
 5. The multi-port datastorage device of claim 1, wherein the multi-port data storage device isa solid state drive (SSD).
 6. The multi-port data storage device ofclaim 1, wherein the multi-port data storage device is a non-volatilememory express (NVMe) data storage device.
 7. The multi-port datastorage device of claim 1, wherein the bridge is configured to decrementa passthru limit of the received one or more data packets.
 8. Themulti-port data storage device of claim 1, wherein the bridge isconfigured to transmit the one or more received data packets withoutusing processors or memory of an external device.
 9. A method fortransmitting data in a multi-port data storage device, the methodcomprising: generating a data packet using a source node of a pluralityof nodes; transmitting the generated data packet to a multi-port datastorage device of a plurality of multi-port data storage devices;receiving the transmitted data packet via a first port of the multi-portdata storage device using a bridge of the multi-port data storagedevice; and transmitting the received data packet via a second port ofthe multi-port data storage device using the bridge to one of anothermulti-port data storage device or to a second node operatively coupledto the multi-port data storage device.
 10. The method of claim 9,wherein transmitting the received data packet further comprisestransmitting the data packet using direct memory access.
 11. The methodof claim 9, wherein transmitting the received data packet may furthercomprise: selecting the one of another multi-port data storage devicebased on egress ID (EID) congestion or bandwidth utilization; andtransmitting the data packet to the selected one of another multi-portdata storage device.
 12. The method of claim 9, wherein transmitting thereceived data packet further comprises transmitting the data packet toone of another multi-port data storage device or to the second nodebased on a destination address of the data packet.
 13. The method ofclaim 9, wherein transmitting the received data packets to one ofanother multi-port data storage device or to the second node is based ona destination address of the data packet.
 14. The method of claim 9,receiving the transmitted data packet comprises receiving the datapacket via direct memory access.
 15. The method of claim 9, wherein themulti-port data storage device is a solid state drive (SSD).
 16. Themethod of claim 9, wherein the multi-port data storage device is anon-volatile memory express (NVMe) data storage device.
 17. The methodof claim 9, further comprising decrementing a passthru limit of thereceived data packet.
 18. The method of claim 9, wherein transmittingthe received data packet comprises transmitting the data packet withoutusing processors or memory of the first and second node.
 19. Aport-to-port network routing system comprising: a source node comprisinga memory and a data bus, the source node configured to: generate a datapacket; and transmit the data packet; a multi-port data storagecomprising: a first port; a second port; and a bridge configured to:receive the transmitted data packet via the first port; and transmit thereceived data packet via the second port to one of another multi-portdata storage device or to a second node operatively coupled to themulti-port data storage device.
 20. The port-to-port network routingsystem of claim 19, wherein the bridge is configured to transmit thedata packet to another multi-port data storage device or to the secondnode based on a destination address of the data packet.